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DOT/FAA/AR-04/41
Office of Aviation ResearchWashington, D.C. 20591
Evaluation of Fuel TankFlammability and the FAA InertingSystem on the NASA 747 SCA
Michael BurnsWilliam M. CavageRobert MorrisonSteven Summer
December 2004
Final Report
This document is available to the U.S. publicThrough the National Technical Information
Service (NTIS), Springfield, Virginia 22161.
U.S. Department of TransportationFederal Aviation Administration
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NOTICE
This document is disseminated under the sponsorship of the U.S.Department of Transportation in the interest of information exchange. TheUnited States Government assumes no liability for the contents or use
thereof. The United States Government does not endorse products ormanufacturers. Trade or manufacturer's names appear herein solelybecause they are considered essential to the objective of this report. Thisdocument does not constitute FAA certification policy. Consult your localFAA aircraft certification office as to its use.
This report is available at the Federal Aviation Administration William J.Hughes Technical Center's Full-Text Technical Reports page:actlibrary.tc.faa.gov in Adobe Acrobat portable document format (PDF).
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Technical Report Documentation Page
1. Report No.
DOT/FAA/AR-04/41
2. Government Accession No.
3. Recipient's Catalog No.
4. Title and Subtitle
EVALUATION OF FUEL TANK FLAMMABILITY AND THE FAA INERTING
SYSTEM ON THE NASA 747 SCA
5. Report Date
December 2004
6. Performing Organization Code
7. Author(s)
Michael Burns, William M. Cavage, Robert Morrison, and Steven Summer
8. Performing Organization Report No.
DOT/FAA/AR-04/41
10. Work Unit No. (TRAIS)9. Performing Organization Name and Address
Federal Aviation Administration
William J. Hughes Technical CenterAirport and Aircraft Safety
Research and Development Division
Fire Safety BranchAtlantic City International Airport, NJ 08405
11. Contract or Grant No.
13. Type of Report and Period Covered
Final Report
12. Sponsoring Agency Name and Address
U.S. Department of TransportationFederal Aviation Administration
Office of Aviation Research
Washington, DC 20591
14. Sponsoring Agency Code
ANM-112
15. Supplementary Notes
16. Abstract
Extensive development and analysis has illustrated that fuel tank inerting could, potentially, be cost-effective if air separation
modules, based on hollow-fiber membrane technology, could be packaged and used in an efficient way. To illustrate this, theFederal Aviation Administration (FAA) has developed a prototype onboard inert gas generation system that uses aircraft bleed air
to generate nitrogen-enriched air (NEA) at varying flows and purities during a commercial airplane flight cycle. A series of
ground and flight tests were performed, in conjunction with National Aeronautics and Space Administration (NASA) aircraft
operations personnel, designed to evaluate the FAA inerting system used in conjunction with a compartmentalized center wingtank (CWT). Additionally, the flammability of both the CWT and one inboard wing fuel tank was measured. The system wasmounted on a Boeing 747, operated by NASA, and used to inert the aircraft CWT during testing. The inerting system, CWT, and
the number 2 main wing tanks were instrumented to analyze the system performance, fuel tank inerting, and flammability.
The results of the testing indicated that the FAA prototype inerting system operated as expected. Using a variable-flow
methodology allowed a greater amount of NEA to be generated on descent when compared to the simple dual-flow methodology,
but it had no measurable effect on the resulting average ullage oxygen concentration after each test, while improving inert gas
distribution by decreasing the worst bay oxygen concentration when three similar tests were compared. The highest averageullage oxygen concentration observed on any flight test correlates directly with the worst bay oxygen concentration, illustrating
the importance of maintaining a low average ullage oxygen concentration in good inert gas distribution. Oxygen diffusion
between the bays of the tank was relatively rapid, and overnight dispersion of the ullage oxygen concentration was measured to be
very small. Flammability measurements showed trends very similar to what was expected based on both experimental and
computer model data. The equilibrium data agreed favorably with data from both the Fuel Air Ratio Calculator and theCondensation Model, while transient data trends matched closely with the Condensation Model with some discrepancies in total
hydrocarbon concentration magnitude at altitude.17. Key Words
Nitrogen-enriched air, OBIGGS, Hollow-fiber membrane, Air
separation module, Total hydrocarbon concentration, Oxygen
concentration, Thermocouple, Pressure transducer
18. Distribution Statement
This Document is available to the public through the National
Technical Information Service (NTIS), Springfield, Virginia
22161 19. Security Classif. (of this report)
Unclassified
20. Security Classif. (of this page)
Unclassified
21. No. of Pages
75
22. Price
Form DOT F 1700.7 (8-72) Reproduction of completed page authorized
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ACKNOWLEDGMENT
The Federal Aviation Administration (FAA) and the Airport and Aircraft Safety Research and
Development Division, Fire Safety Branch would like to acknowledge the contributions of
NASA Johnson Space Center in supporting the extensive installation of equipment and
instrumentation to accomplish the very difficult task of studying in-flight flammability and fueltank inerting during flight tests on the NASA 747 SCA. Additionally, acknowledgement goes to
the excellent test pilots and crew that supported the lengthy and time-consuming flight test plan
provided by the FAA. The dedication and professionalism of the entire test and support personnel at Ellington Field, particularly the zero-g team, which allowed the FAA to achieve the
project goals and objectives was significant, and their technical know-how and professionalism
are the primary reasons for the success of the test program.
Further acknowledgement is extended to NASA Glen Research Center Fire Safety Research
Program for lending financial and moral support to the project when it was needed most.
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TABLE OF CONTENTS
Page
EXECUTIVE SUMMARY xi
1. INTRODUCTION 1
1.1 Background 1
1.2 Scope 2
2. TEST ARTICLE AND PROCEDURES 2
2.1 Test Article 2
2.1.1 Aircraft 2
2.1.2 Instrumentation 52.1.3 Aircraft Cabin Installation 12
2.2 Test Procedures 16
3. ONBOARD INERT GAS GENERATION SYSTEM 18
3.1 System Flow 18
3.2 System Interfaces 20
3.2.1 System Mounting 20
3.2.2 Mechanical Interface 20
3.2.3 Electrical Interface 22
3.3 System Operation 22
4. ANALYSIS 23
4.1 Inerting Calculations 24
4.1.1 Bleed Air Consumption 244.1.2 Average Fuel Tank Oxygen Concentration 24
4.1.3 Inerting Model 24
4.2 Flammability Calculations 25
4.2.1 Estimation of the Vapor Generation in the CWT 254.2.2 Fuel Air Ratio Calculator 25
5. DISCUSSION OF RESULTS 26
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5.1 Fuel Tank Inerting 26
5.1.1 Inerting System Performance 26
5.1.2 Ullage Oxygen Concentration Data 34
5.2 Fuel Tank Flammability 42
5.2.1 General Flammability Trends 42
5.2.2 Temperature Effects 435.2.3 Cross-Venting Effects 45
5.2.4 Comparison of Calculations 48
6. SUMMARY OF FINDINGS 52
7. REFERENCES 52
APPENDICES
A—Center Wing Tank Instrumentation Panel Installation Drawing
B—Heated Gas Sample Fittings Installation Drawing
C—Instrumentation Diagram With Channel Listing
D—Surface-Mounted Thermocouple Drawing
E—Onboard Inert Gas Generation System Mechanical Drawing With Interface
Illustration
F—Onboard Inert Gas Generation System Inert/Divert Tubing Assembly Top Drawing
G—Nitrogen-Enriched Air Deposit Nozzle Installation Drawing
H—Onboard Inert Gas Generation System Wiring Diagram
I—Test Fuel Flashpoint and Distillation Data
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LIST OF FIGURES
Figure Page
1 NASA 747 SCA Aircraft With Space Shuttle Orbiter 3
2 NASA 747 SCA Fuel Tank Diagram 3
3 Modified Rear Spar Purge Door 4
4 (a) Rack-Mounted FAS Installation and (b) NDIR Analyzer 7
5 The FAS Sample Stream Flow Schematic 7
6 Top View of a 747-100 CWT With Sample Port Locations 8
7 Gas Sample Float Valve Installation 9
8 Top View of a 747-100 CWT With Thermocouple Locations 10
9 Top View of a 747-100 Wing Tank With Thermocouple Locations 11
10 Master DAS Display 13
11 Power Distribution for the NASA 747 SCA Cabin 14
12 Modified Waste Shoot Used as a Conduit at the Aft Pack Bay Area Bulkhead 15
13 Diagram of Instrumentation Installation in the NASA 747 SCA Cabin 16
14 System Block Diagram 18
15 Three-Dimensional Rendering of the OBIGGS Installed in the Pack Bay 20
16 Onboard Inert Gas Generation System Installed in Test Aircraft Pack Bay 22
17 Front Panel of OBIGGS Control Box 22
18 System Performance Data for a Typical Flight Test 26
19 Comparison of ASM Pressure During the Inception of Three Different Flight
Tests With Altitude 27
20 Comparison of NEA Purity During the Inception of Three Different Flight Tests
With Altitude 28
21 Comparison of NEA Flow During the Inception of Three Different Flight Tests
With Altitude 28
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22 Comparison of ASM Input and Output Conditions During the Inception of Three
Different Flight Tests 29
23 Comparison of ASM Pressure During the Descent Phase of Three Different Flight
Tests With Altitude 30
24 Comparison of NEA Purity During the Descent Phase of Three Different FlightTests With Altitude 30
25 Comparison of NEA Flow During the Descent of Three Different Flight Tests
With Altitude 31
26 Comparison of Bleed Air Consumption During the Inception of Three Different
Flight Tests With Altitude 32
27 Comparison of Bleed Air Flow During the Descent of Three Different Flight
Tests With Altitude 32
28 Correlation of NEA Flow With ASM Pressure for the System Low-Flow Mode
for Three Different Flight Tests 33
29 Correlation of NEA Flow With ASM Pressure for the System Variable/High-FlowMode for Three Different Flight Tests 34
30 Oxygen Concentration Data From all Six Bays With Test Altitude for a TypicalFlight Test 35
31 Average Ullage Oxygen Concentration Data Calculated From Six Bay
Measurements With Test Altitude for a Typical Flight Test 35
32 Comparsion of Average Ullage Oxygen Concentration With Four Different Test
Descent Profiles 36
33 Comparsion of the Worst Bay Oxygen Concentration With Four Different Test
Descent Profiles 37
34 Correlation of the Peak Worst Bay Oxygen Concentration With the Peak Average
Ullage Oxygen Concentration for Four Different Test Descent Profiles 37
35 Average Ullage Oxygen Concentration Data for a Typical Flight Test Compared
to a Simple Ullage Inerting Model 38
36 Oxygen Concentration Data for the Six Bays of the CWT During the Descent of a
Typical Flight Test 39
37 Variation in the Oxygen Concentrations in the Six Bays of the CWT During
Three Flight Tests 40
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38 Comparsion of the Ullage Oxygen Concentration for all Six Bays During a
3-Hour Turnaround 41
39 Comparsion of Oxygen Concentration for all Six Bays During a 24-Hour
Overnight Period With a Fuel Transfer 42
40 Flight Test 5 THC and Ambient Pressure Measurements 43
41 Flight Test 5 CWT THC and Temperature Measurements 44
42 Flight Test 5 Wing Tank THC and Temperature Measurements 44
43 Flight Test 4 CWT THC and Temperature Measurements 45
44 Flight Test 0 CWT THC and Ambient Pressure Measurements 46
45 Flight Test 6 CWT THC and Ambient Pressure Measurements 46
46 Flight Test 0 CWT Temperature Measurements 47
47 Flight Test 6 CWT Temperature Measurements 47
48 Measured and Computed Equilibrium THC Values 49
49 Center Wing Tank THC Measured and Computed Results for a Ground Test 50
50 Measured and Calculated THC Measurements for Flight Test 3 50
51 Measured and Calculated THC Measurements for Flight Test 4 51
52 Measured and Calculated THC Measurements for Flight Test 5 51
LIST OF TABLES
Table Page
1 Wing Tank Thermocouple Locations 11
2 Table of Inerting Flight Tests on the NASA 747 SCA 17
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LIST OF ACRONYMS
ACM Air cycle machines
ASM Air separation modules
CWT Center wing tank
DAS Data acquisition systemFAA Federal Aviation Administration
FAR Fuel air ratio
FAS Flammability analysis systemID Inner diameter
LOC Limiting oxygen concentration
NASA National Aeronautics and Space Administration NEA Nitrogen-enriched air
OBIGGS Onboard inert gas generation system
OBOAS Onboard oxygen analysis systemOEA Oxygen-enriched air
SCA Space Shuttle Orbiter Carrier AircraftSCFM Standard cubic feet per minute
SOV System shutoff valveSTA Station
THC Total hydrocarbon concentration
WS Wing station
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EXECUTIVE SUMMARY
Significant emphasis has been placed on fuel tank safety since the TWA Flight 800 accident in
July 1996. This has prompted the Federal Aviation Administration (FAA) to study methods that
could limit the flammability exposure of the commercial transport fleet. The effort was focused
on high-flammability exposure fuel tanks, which are center wing and body-style fuel tanks.Extensive development and analysis has illustrated that fuel tank inerting during aircraft
operation could, potentially, be cost-effective if air separation modules (ASM) could be
integrated into a system and used in an efficient manner. These ASMs are made of thousands oftiny, hair-sized, hollow-fiber membranes, which are fabricated into a vessel. When supplied
with pressurized air, these modules will ventilate a waste stream of gas from a permeate vent that
is rich in oxygen, carbon dioxide, and water vapor. This allows the product gas passing throughthe ASM to be rich in nitrogen.
To demonstrate using hollow-fiber membrane ASMs for inerting commercial transport airplanefuel tanks, the FAA, with the assistance of several aviation-oriented companies, has developed a
prototype onboard inert gas generation system with ASMs that uses aircraft bleed air to generatenitrogen-enriched air (NEA) at varying flows and purities (NEA oxygen concentration) during a
commercial airplane flight cycle. This system was designed to maintain an oxygen concentration below 12% in a Boeing 747 center wing tank (CWT) during typical commercial transport
airplane operations. A series of ground and flight tests were performed, in conjunction with
National Aeronautics and Space Administration (NASA) aircraft operations personnel, designedto evaluate the simplified inerting system and examine inerting of a compartmentalized fuel tank.
Additionally, the flammability of both the center wing and one inboard wing fuel tank was
examined. The FAA inerting system was mounted in the pack bay of a modified 747, operated by NASA for Space Shuttle Orbiter transportation, and used to inert the aircraft CWT during
testing. The inerting system, CWT, and the number 2 wing tanks were instrumented to analyzesystem performance, inerting capability, and fuel tank flammability.
The results of the testing indicated that the FAA inerting system operated as expected. Anydeviations in system performance from test to test could be explained by the difference in system
warmup times on the day of the test. Using a variable flow methodology allowed for a greater
amount of NEA to be generated on descent at a higher oxygen concentration (lower purity) as
intended, but it had no measurable effect on the resulting average ullage oxygen concentrationafter each test when compared to a simple dual-flow system methodology. It did seem to
improve inert gas distribution by decreasing the worst bay oxygen concentration. The highest
average ullage oxygen concentration observed on any flight test correlated directly with theworst bay oxygen concentration. Oxygen diffusion between the bays of the tank was relatively
rapid, and the overnight increase of the ullage oxygen concentration was measured to be very
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small. Flammability measurements from both the CWT and the wing tank showed trends very
similar to what was expected based on both experimental and computer model data. Theequilibrium data agreed favorably with data from both the Fuel Air Ratio Calculator and the
Condensation Model, while transient data trends matched closely with the Condensation Model,
with some disagreement with flammability magnitudes at altitude. The measurements generated
in these flight tests have been used to enhance the capability of these existing flammabilitymodels and will be used in the future to further improve the predictive flammability calculations.
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1
1. INTRODUCTION.
1.1 BACKGROUND.
Significant emphasis has been placed on fuel tank safety since the TWA Flight 800 accident in
July 1996. This has prompted the Federal Aviation Administration (FAA) to study methods that
could limit the flammability exposure of the commercial transport fleet. The effort was focusedon center wing and body-style fuel tanks that have been identified as being potentially hotter
during ground operations and more flammable in general [1]. Extensive development and
analysis has illustrated that flammability reduction using fuel tank inerting during aircraftoperation could, potentially, be cost-effective if air separation modules (ASM) could be
integrated into a system and used in an efficient manner. To illustrate this, the FAA, with the
assistance of several aviation-oriented companies, developed a prototype onboard inert gas
generation system (OBIGGS) with ASMs that used aircraft bleed air to generate nitrogen-enriched air (NEA) at varying flows and purities (NEA oxygen concentration) during a
commercial airplane flight cycle. This system was designed to maintain an oxygen concentration
below 12% in a Boeing 747 center wing tank (CWT) during typical commercial transportairplane operations. An ASM is made up of thousands of tiny, hair-sized, hollow-fiber
membranes, which are fabricated into a vessel. When supplied with pressurized air, these
modules will ventilate a waste stream of gas from a permeate vent that is rich in oxygen, carbondioxide, and water vapor [2]. This allows the product gas passing through the ASM to be rich in
nitrogen.
Early ASM OBIGGS work performed by the Department of Defense culminated in a study that
highlighted the favorable life cycle costs of an on-demand (inert gas generation) system over a
stored inerting agent system and explosive suppressant foam. This study concluded that an
inerting system using ASMs with hollow-fiber membrane technology was cost-effectivecompared to other OBIGGS technologies with a relative performance increase of a factor of ten
over previous ASM technology systems [3].
The initial FAA fuel tank inerting flight tests were performed in conjunction with The Boeing
Company to examine the ability of a ground-based supply of nitrogen (ground-based inerting) toinert a commercial airplane CWT. This allowed for validation of the FAA’s Onboard Oxygen
Analysis System (OBOAS) during flight-testing, which was developed for the project and could
continuously measure the oxygen concentration of a commercial transport fuel tank ullage usingconventional laboratory oxygen analyzers and a pressure-controlled sample train [4]. Recent
FAA flight tests were performed in conjunction with Airbus to test the FAA inerting system,
which was mounted in the cargo bay of an A320 operated by Airbus, for the purpose of researchand development. The system performance was degraded to examine the ability of a single ASM
and two ASMs to inert the CWT of the test aircraft and to help develop a system performancemodel. The basic dual-flow system concept was validated and system scaling was examined.
The effects of fuel and inert gas distribution were also studied, and a simply ullage inertingmodel was developed to calculate ullage oxygen concentration given a system performance and
flight cycle [5].
Much of the flammability research performed by the FAA has focused on the determination of
the limiting oxygen concentration (LOC), the oxygen content below which ignition of jet fuel
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2
vapors can no longer be supported. The LOC is the main design criteria for any inerting system,
because it determines the oxygen levels required to provide adequate fuel tank explosion protection. Traditionally, the military has used a value of 9 percent oxygen by volume as the
inert limit of a fuel tank ullage. An experimental investigation performed by the FAA using a 9-
cubic-foot test article illustrated, however, that no measurable pressure rise was observed when a
spark was used to ignite a flammable ullage with an oxygen concentration less than 12 percent by volume at sea level and 10,000 feet. The LOC value increased in a linear fashion to
approximately 14.5 percent oxygen at 40,000 feet [6]. The experiment used a small fuel pan,
radiantly heated from underneath, with the test article in a vacuum chamber to study the abilityof a simulated ullage to react to a spark source applied under a variety of conditions. Follow-on
experiments studied a wide variety of fuel/air mass ratios and ignition sources/energies with no
change in the resulting LOC. A review of previously published literature showed very goodagreement with measured results.
1.2 SCOPE.
The FAA, with the assistance of National Aeronautics and Space Administration (NASA)
aircraft operations, performed a series of ground and flight tests designed to study the simplifiedinerting concept developed by the FAA. The FAA developed a prototype inerting system, based
on ASM technology, designed to maintain an inert ullage in the CWT of a 747 commercial
transport during normal ground and flight operations using a dual-flow methodology. Theinerting system was mounted in the pack bay of a NASA 747 Space Shuttle Orbiter Carrier
Aircraft (SCA) to perform the FAA-managed test plan. The system was interfaced with the
aircraft systems, and instrumentation was installed to measure the inerting system performanceand fuel tank flammability during the flight tests. Both the CWT and the number 2 wing fuel
tank (here after referred to as the wing tank) were instrumented with gas sample tubing and
thermocouples to allow for real-time monitoring of total hydrocarbon concentration,temperatures, and CWT ullage oxygen concentration distribution during each test flight.
2. TEST ARTICLE AND PROCEDURES.
2.1 TEST ARTICLE.
The test article consisted of a NASA 747 SCA associated instrumentation and data acquisitionsystem (DAS). The FAA OBIGGS with associated instrumentation was installed in the pack
bay. The CWT was instrumented with eight gas sample tubes that were routed to the FAA’s
OBOAS, a heated gas sample port routed to the FAA Flammability Analysis System (FAS), as
well as multiple temperature probes. The wing tank was instrumented with both a heated gassample port for the FAS and multiple temperature probes as well.
2.1.1 Aircraft.
The test article was a 747-100, highly modified by NASA, as an SCA (figure 1). It has a basic
operating weight of 318,053 lbs with a gross taxi weight of 713,000 lbs. It has a 195′ 8″ wing
span and is 231′ 10″ long. The maximum cruise speed of the aircraft is 250 knots or Mach 0.6with a ceiling of 35,000 feet.
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FIGURE 1. NASA 747 SCA AIRCRAFT WITH SPACE SHUTTLE ORBITER
Figure 2 shows the four main wing fuel tanks, the two wing tip reserve fuel tanks, and the large
CWT of the NASA 747 SCA. The CWT has a capacity of 12,890 gallons of fuel and is between
the wings of the aircraft, within the fuselage of the aircraft (center wing box). The CWT isapproximately 242 inches long and 255 inches wide with a height varying from 78 inches to 48
inches and is partitioned into six bays, two bays are the full width of the fuselage, while another
two full-length bays are bisected mid-way with a partial rib creating four bays. The empty CWTullage volume was determined to be 1775 normal cubic feet for the purpose of inerting the tank
with NEA. A large dry bay exists in the center wing box forward of the first tank bay.
Immediately below the CWT, in an area known as the pack bay, are three air cycle machines
(ACM) that provide conditioned air to the aircraft and rejects heat to the CWT.
Forward No. 2
Main
Tank
Center
Wing
Tank
No. 3
Main
Tank No. 1
Main
Tank
No. 4
Main
Tank No. 4Reserve
Tank
No. 1Reserve
Tank
Surge
Tank
Surge
Tank
Dry
Bay
Dry
Bay
FIGURE 2. NASA 747 SCA FUEL TANK DIAGRAM
3
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The CWT is vented to both wing tip surge/vent tanks via a vent channel in each wing that is
plumbed to vent tubing contained within the tank. One vent channel travels along the top of bays3 and 4, while the other travels along the top of bays 5 and 6. These channels vent crosswise to
the exterior of the tank so that the vent channel plumbed on the right side of the tank (bays 5 and
6) is vented to the left wing surge/vent tank and vise-versa. Each vent channel is plumbed to a
length of aluminum tubing on each side of the tank that travels forward perpendicular to thespanwise beams and midspar across the bays. A smaller tube travels aft within the vent channel
bay. This plumbing configuration allows the CWT to vent pressure in various rolling and
climb/dive scenarios. The vent channels from the CWT and all other fuel tanks terminate in oneor both of the surge/vent tanks located near each wing tip. These surge/vent tanks catch fuel and
prevent overflow, and are connected to the aircraft exterior via a NACA scoop located on the
bottom surface of each wing.
2.1.1.1 Replacement of Ventilation Port With Instrumentation Panel.
The 747 has a ventilation port on the rear spar to ventilate the CWT with fresh air during
maintenance operations. The FAA installed an instrumentation panel in place of the CWT
ventilation purge door on the rear spar as shown in figure 3, allowing easy passage ofinstrumentation to and from the CWT. The instrumentation panel accommodated ten bulkhead
fittings for the gas sample lines as well as two thermocouple bulkhead ports for sealing the
thermocouples at the rear spar. There was also a 1-inch bulkhead fitting in the center of the panel for the NEA deposit line. The installation drawing for the instrumentation panel is shown
in appendix A.
FIGURE 3. MODIFIED REAR SPAR PURGE DOOR
2.1.1.2 Modification to the Vent System.
As described above, the 747 aircraft vents the CWT to both wing tip surge (overflow) tanks.Cross venting is the process by which subtle pressure changes between these vents allow outside
air to ventilate the ullage by passing through one vent channel, into the tank, and out of the other
vent channel.
4
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5
To prevent the loss of inert gas by this process, the FAA installed three blocking plates in the
right side vent system (looking forward) of the NASA 747 SCA. One was installed by removingthe vent flange that attached the vent tubing to the vent channel, placing a thin aluminum plate
between the flange and the vent stringer and sealing it with fuel tank sealant. In addition, the 4-
inch-diameter vent tube also had a thin, round aluminum plate installed in one connection fitting
to prevent inert gas from transferring through the tube from one bay to another. It was notnecessary to use fuel tank sealant on this blocking plate. The right side vent stringer also has a
fuel drain with a float valve mounted on it. The float valve was removed and a blocking plate
was installed in its place and sealed with fuel tank sealant. This modification prevents crossventing of the CWT ullage.
After the FAA completed the tests to examine inerting without cross venting, the vent systemwas restored to the original equipment configuration for a single baseline flammability test.
2.1.1.3 Gas Sample Fittings.
Two sample port tubes were installed through modified HiLok ® fasteners, which were installed
in place of specified existing fasteners in the wing structure, to allow for the measurement of
total hydrocarbons in both the CWT and the wing fuel tank. In each case, an appropriate fastener
was specified, modified with a 1/8-inch hole through the fastener center, and then installed in theappropriate location. The CWT fitting penetrated the top of the tank in the number 2 bay slightly
left of centerline, while the wing tank fitting was located just outboard of the number 2 engine
pylon on the front spar. The sample port tubes were later bonded into the fastener holes withaviation grade epoxy, and float valve assemblies were installed on the tube inside the tank to
prevent sloshing fuel from entering the sample lines attached to the tubing outside of the tank. A
drawing illustrating the hollow-fastener installation with float valve assemblies is shown inappendix B. There was a third tooling hole fastener modified on the left wing forward spar to
accommodate the eight thermocouples installed in the number 2 main fuel tank. When
completed, the installation was sealed with the appropriate fuel tank sealant.
2.1.2 Instrumentation.
The primary instrumentation centered around the heated and unheated gas-sampling tubing and
thermocouples in both the CWT and the wing tank. Continuous measurement of oxygenconcentration and total hydrocarbon concentration (THC) in the fuel tanks during each flight test
were made using the FAA OBOAS and FAS. Additionally, the FAA OBIGGS was instrumented
with pressure, temperature, oxygen concentration ports, and a flow sensor to analyze system performance and health monitoring for each test. Additional test parameters were also collected
to aide in the analysis of the inerting process and progression of flammability during the flight
tests. Appendix C contains a complete instrumentation diagram as well as a complete list of allinstrumentation channels.
2.1.2.1 Onboard Oxygen Analysis System.
The FAA OBOAS was used to measure the oxygen concentrations at the eight specified
locations within the CWT. The OBOAS was developed by the FAA to measure the oxygenconcentrations in a fuel tank environment during a typical commercial-transport airplane flight
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6
cycle using conventional oxygen analyzers. This system consists of a regulated sample train
with flow-through, in-line oxygen sensors and ancillary equipment. Two identical four-channelsystems were developed. Each four-channel system was self-contained in a 19-inch flight test
half-rack. Each system has four independent sample trains that can draw an ullage sample at
four different locations in the fuel tank, regulate the sample pressure, expose the sample to the
oxygen sensor, and redeposit the sample back into the fuel tank. Each oxygen sensor has acompanion analyzer mounted on the same 19-inch half-rack. Also mounted on each 19-inch
half-rack is a four-channel inlet pressure controller and a single-outlet pressure controller
electronic unit. These electronic units support the five pressure regulator/controllers in eachfour-channel system. Reference 7 gives a complete description of the measurement system with
part lists, diagrams, and systems analysis.
2.1.2.2 Flammability Analysis System.
The FAA developed the FAS for the purpose of real-time, in-flight monitoring of the THC in
both the CWT and wing tank. The FAS consists of a two-channel Rosemount Analytical NDIR
analyzer, supplied by temperature-controlled, pressure- and flow-regulated sample streams. The
NDIR analyzer was custom-designed and constructed by the manufacturer to safely measure fueltank vapors in flight and housed in an explosion proof box.
All hydrocarbon gas samples must be maintained at a minimum 200°F temperature prior toentering the NDIR analyzer to eliminate any condensation of the hydrocarbon vapors prior to
being measured. To that end, the sample stream external to the FAS consists of several heatedsample tubes and a heated rack-mounted box, which houses the diaphragm pump heads, flash
arrestors, float valves, sample control valves, and sample flow meters. A separate unheated,
rack-mounted box houses the two inlet sample pressure regulators. For safety, both rack-mounted boxes are continuously purged with air in the same manner as the OBOAS to prevent
the accumulation of explosive vapors in the event of a sample line leak. An additional rack-
mounted panel houses all necessary electronics to maintain the proper sample conditions,including temperature controllers and the pressure controller electronic units.
Figure 4(a) shows a diagram of the rack-mounted installation of the pump, sample-conditioning
boxes, and controller box, and figure 4(b) shows the NDIR analyzer.
2.1.2.2.1 Sample Train Flow.
After entering the FAS heated rack-mounted box, the samples pass through a flash arrestor andthen a four-way selector valve. The selector valve enables the operator to draft a sample from
the tank, cabin air, calibration gases, or to close off the sample inlet. Each sample then passes
through a two-stage diaphragm pump. Prior to exiting the heated rack-mounted box, the samplesare teed off to the inlet pressure regulators located in the sample-conditioning unit, whichregulates the inlet pressure. On the other side of the tee, the samples pass through a sample flow
meter prior to exiting the heated rack-mounted box. Another heated line then routes the samples
to the NDIR analyzer. On the exit side of the NDIR analyzer, the two samples are joinedtogether and dumped overboard after flowing through a manual backpressure regulator.
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Heated Sample
Box
Sample
Flow/PressureConditioning Unit
ControllerElectronics Panel
(a)(b)
FIGURE 4. (a) RACK-MOUNTED FAS INSTALLATION AND (b) NDIR ANALYZER
In the event that a float valve is actuated and flow through that line is blocked, the operator has
the capability to purge that line once it drops below the fuel level. This is accomplished by
sampling from the cabin and circulating that sample back through the closed portion of the lineuntil the float opens back up. A schematic of the sample train flow is shown in figure 5.
FIGURE 5. THE FAS SAMPLE STREAM FLOW SCHEMATIC
2.1.2.2.2 System Safety Features.
Careful measures were taken to ensure that the FAS operates in such a manner to minimize the
operator’s and crew’s exposure to hazardous vapors as well as to preclude the ignition of any
potentially flammable vapors that may be drafted through the FAS.
The NDIR analyzer is housed within a continuously purged housing with an impact-tested,
intrinsically safe front panel. The electronics of the NDIR analyzer have been separated from the
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sample stream to allow safe heating of all internal sample tubes to 200°F as well as to separateany potential ignition sources from the sample stream in the event of a leak of flammable vapors.
The purge system incorporated an easily observed indicator of a safe or nonsafe condition in theform of a rotary flow indicator. If purge pressure was unable to maintain a safe condition, the
unit was immediately shutdown. The purge system for the rack-mounted sample-conditioning boxes used two ejectors each requiring a minimum of 3 standard cubic feet per minute (SCFM)
of compressed air at 40 psi or greater. The ejector unit maintained a constant negative pressureon the inlet, drafting a volume of air from inside the boxes. The ejector inlet is plumbed through
a rotary flow indicator, which allowed the operator to determine if the purge flow is functional at
any point in time.
Likewise, the rack-mounted sample-conditioning boxes, housing the pump, flow meter, and
sample pressure regulators, are continuously purged enclosures and are separated from the rack-mounted panel housing the control electronics (temperature controllers and pressure control
electronic units). In addition, care has been taken to only mount the diaphragm pump head
inside the heated box. The motor driving the diaphragm pump was kept external to the box,again to maintain separation between any electrical sources and the sample stream flow.
2.1.2.3 Gas-Sampling Lines.
Eight sample ports are located in the CWT at the eight locations identified in figure 6. The
sample lines are made of PFA tubing routed from bay 6 to each location through the fuel seepholes at the top of the tank between the spars/spanwise beams and the side of body ribs. The
tubing is terminated at a float valve that is attached to the tank through a mounting plate that was
attached to a stiffening bracket between two stringers (with a stiffener) at the top of the tank.This small plate is attached to the stiffener bracket through a replaced rivet to minimize the
necessary modification for the installation. Figure 7 shows one sample port mounting plate
attached in the CWT with a float valve assembly.
FIGURE 6. TOP VIEW OF A 747-100 CWT WITH SAMPLE PORT LOCATIONS
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FIGURE 7. GAS SAMPLE FLOAT VALVE INSTALLATION
2.1.2.4 Heated Sample Lines.
The fuel vapor samples were drafted from the fuel tanks via the installed sample fittings (see
section 2.1.1.3). After exiting the tanks, the samples were routed to the FAS using a series of
heated sample lines maintained at a constant 200°F. For the CWT sample, a single 10-footheated line was routed directly from a modified fastener at the top of the tank to the rack-
mounted portion of the FAS. The sample from the wing tank was routed from a similarlymodified fastener on the front spar, down the leading edge of the left aircraft wing with a 50-footheated line. This line was routed to a fitting on the fuselage pressure bulkhead with a separate
heated line routed from this fitting, into the front cargo bay, and to the FAS. The temperature of
all heated lines along with the heated box was continuously monitored by the operator via panel-mounted displays. In addition, the 50-foot line was constructed to have additional
thermocouples located every 5 feet along the line that were recorded by the DAS.
2.1.2.5 Fuel Tank Thermocouples.
There were 24 thermocouples mounted in the CWT positioned at the locations identified in
figure 8. The T-type thermocouples were routed through compression fittings on the instrument panel and sealed with fuel tank sealant. Fourteen of these thermocouples were mounted on
metallic surfaces with an epoxy-retaining patch (appendix D), while the remainder weresuspended at the desired location. The thermocouples were mounted to the tank structure using
fuel-compatible wire ties with some long runs being supported by additional epoxy patches. The
thermocouples were 1/16-inch stainless steel sheathed and ran from the panel installed in bay 6to each desired location through the fuel seep holes at the top and bottom of the tank between the
spars/spanwise beams and the side of the body ribs.
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Side of
Body Rib
Side of
Body Rib
FIGURE 8. TOP VIEW OF A 747-100 CWT WITH THERMOCOUPLE LOCATIONS
The ullage thermocouples (1 through 8) were installed within 1 foot of the bottom of the caps of
the ceiling stringers. The fuel thermocouples (21 and 22) were installed less than 1 inch from thetank bottom. Thermocouples 9 through 16 were mounted on the floor. Thermocouples 17-20
were mounted on the tank walls approximately half way between the bottom and the top of thetank. Thermocouples 23 and 24 were mounted on the ceiling of the tank.
There were eight thermocouples mounted in the wing tank, positioned as described in table 1.The thermocouples were the same type used in the CWT and were routed from the cabin,
through the cargo bay, into the fairing area, along the leading edge, and through a drilled out
tooling hole on the front spar of the wing approximately at wing station (WS) 400. Five of thesethermocouples were mounted on surfaces in the same manner as in the CWT, with the remainder
suspended at the desired location. Figure 9 gives a top diagram of wing tank number 2 with the
approximate location of the thermocouples noted.
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TABLE 1. WING TANK THERMOCOUPLE LOCATIONS
Temp
No. Description Location
1 Wing tank forward spar surface
temperature
Front spar surface, WS 455, 25″ from tank
bottom2 Wing tank inboard fuel
temperature4′ from front spar, WS 310, 6″ from tank bottom
3 Wing tank rear spar surface
temperatureRear spar surface, WS 435, 25″ from tank
bottom
4 Wing tank ullage temperature 2″ from front spar, WS 650, 4″ from tank top
5 Wing tank mid-fuel/ullagetemperature
25″ from front spar, WS 586, 13" from tank bottom
6 Wing tank outboard wall surfacetemperature
6′ from front spar, WS 715, 12″ from tank
bottom7 Wing tank bottom surface
temperature8′ from front spar, WS 455, tank bottomsurface
8 Wing tank top surface temperature 8′ from front spar, WS 455, tank top surface
Ullage Gas SampleLocation
1
2
4
3
5
6
78
WS 400
WS 630
WS 455
WS 586
WS 499
Thermocouple
Penetration
Front Spar
#2 Engine
Pylon
FIGURE 9. TOP VIEW OF A 747-100 WING TANK WITH
THERMOCOUPLE LOCATIONS
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2.1.2.6 Onboard Inert Gas Generation System Parameters.
The FAA OBIGGS was equipped with instrumentation that monitored and set system
parameters. The instrumentation was routed from the OBIGGS mounted in the empty right side,
rear pack bay area to the cabin. The inerting system was instrumented with six thermocouplesand four pressure taps to monitor system health and performance. Pressure transducers, used to
monitor the system pressures, were mounted on a panel in the cabin with pressure-sensing tubes
routed from the pressure taps to the transducer panel. All OBIGGS pressure tap and temperaturemeasurement locations are identified on the OBIGGS drawing given in appendix E.
Additionally, ambient pressure was measured in the pack bay for data reduction.
The OBIGGS was also equipped with gas-sampling ports to measure both NEA and oxygen-
enriched air (OEA) oxygen concentrations, also shown on the drawing in appendix E. These
oxygen samples were monitored by a two-channel oxygen analyzer capable of sampling fromaltitude, which operated very similar to the OBOAS. This oxygen analyzer did not require fluid
traps, flash arrestors, or containment box purging because the sample system did not acquire a
sample from a potentially flammable source. Also, a flow meter was installed at the NEA output
to measure the NEA flow rate. These parameters constituted the ASM performance at a givenflight condition.
2.1.2.7 Additional Parameters Collected.
Additional instrumentation was employed to determine the validity of certain data and to betterunderstand the fuel tank inerting process, in general, as it relates to the FAA concept. Static
pressure was measured, allowing examination of the effect of altitude on the inerting process.
The NEA temperature at the flow meter and the backpressure on the OEA line was also acquired.
Thermocouples were also located in the pack bay (4), one of which was in the immediate area ofthe OBIGGS. An additional three thermocouples were installed in the area of the bleed air
connection to the system. This allowed for redundant measurement of temperature in the area ofthe pack bay that could potentially be susceptible to a bleed air leak.
2.1.2.8 Data Acquisition System.
A DAS recorded all analog signals required for the test in a multiplexed method and stored thedata on the flight test data acquisition computer. Some data were presented on a master display,
in a block diagram format, to facilitate real-time monitoring of the more significant parameters
during the testing. Figure 10 shows the master DAS display.
2.1.3 Aircraft Cabin Installation.
All instrumentation was routed to the cabin via several different cabin penetrations to an array of
FAA-designed and built instrumentation racks installed in the central part of the pressurized
cabin immediately above the CWT. All instruments, as well as the OBIGGS, were powered viaan extensive power distribution panel wired to an existing work rack immediately forward of the
FAA rack system.
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FIGURE 10. MASTER DAS DISPLAY
2.1.3.1 Power Distribution.
All power required to run the OBIGGS and the test instrumentation was obtained from anextensive power distribution bus located on an existing utility rack at station (STA) 990. The
OBIGGS required both 115 Vac, three-phase 400 Hz and 28 Vdc power to operate. Each rack(2) in the OBOAS required 115 Vac, three-phase 400 Hz to operate an accompanying 115 Vac,single-phase 60-Hz power voltage converter rated for 20 amps. The two voltage converters are
used to power the OBOAS as well as the OBIGGS oxygen analysis system with a power
switching system attached to the OBOAS rack system.
An existing 60-cycle power converter was used in conjunction with an additional NASA power
converter to power the FAS with the associated instrumentation. This included the NDIRanalyzer, all heated lines, and pressure controllers. Additionally, the computer and DAS were
powered by this set of power converters using an uninterruptible power supply. Figure 11
illustrates the distribution of power for the flight test instrumentation and DAS.
2.1.3.2 Instrumentation Routing.
The CWT thermocouples were routed from the modified rear spar purge door into the cabin
through an existing wiring penetration in the right-hand wheel well at STA 1275. The DAS was
located on the same rack with the OBIGGS control box and gas analysis equipment. The wingtank thermocouples were routed from a modified fastener in a tooling hole on the front spar,
along the front spar into the fairing area, and into the fuselage through another wiring penetration
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at STA 985. These thermocouples were routed to the DAS rack under the floor in the cargo bay
to the right side of the cabin.
OBIGGS
Analysis Pump
OBOAS
Pump 1
OBOAS
Pump 2
OBOAS Rack Assembly
OBIGGS
Control
Box
DAS
Computer
DAS &
OBIGGS
Rack
NDIR
Analyzer
Sample
System
FAS
Rack
UPSPower Strip
115 VAC, 400 Hz BusAdditional
60 Hz Power
Converter
28 VDC Bus
Existing Power Rack
OBIGGS AnsySample Train
Existing
60 Hz Power
Converter
Sample
Pump
FIGURE 11. POWER DISTRIBUTION FOR THE NASA 747 SCA CABIN
The eight CWT gas-sample lines and two sample return lines were routed from the rear spar
purge door fittings to the OBOAS in the cabin via a cabin penetration in the wheel well adjacent
to the thermocouple penetration (approximate STA 1250). The CWT gas-sample lines were
routed into the cabin through a mating fixture that terminated the shrouds of the eight samplelines and two returns in the cabin area. The lines were routed to the OBOAS location in the
center of the aircraft adjacent to the DAS rack aft of STA 1080. Each four-channel system had a
gas sample return routed to the tank through the same mating fixture to minimize the effect ofthe sample system on the ullage environment. The signals from the eight oxygen analyzers were
routed to the DAS.
For the CWT THC gas sample, a single 10-foot heated line was routed directly from a modified
fastener in the cabin near STA 1100 to the FAS rack located on the left side of the cabin near
STA 1030. The sample from the wing tank was routed from a similarly modified fastener atWS 630 on the front spar to a 50-foot heated line routed down the leading edge of the left aircraft
wing, through an existing hole between the leading edge and the fairing area, to a bulkhead
fitting on the fuselage pressure bulkhead in the front cargo bay at STA 985. From this fitting,
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another 10-foot heated line conveyed the sample to the rack-mounted portion of the FAS. The
FAS also required two heated lines between the FAS rack and the NDIR analyzer immediatelyadjacent to the rack at approximately the same fuselage station. Signals from the FAS were
routed across the cabin to the DAS rack.
The control cable for the OBIGGS was routed from the OBIGGS in the pack bay to the OBIGGScontrol box through a modified waste shoot that provided a conduit to the cabin from the aft
bulkhead of the pack bay (figure 12). All OBIGGS instrumentation, including gas-sampling
tubing, pressure-sensing tubing, and thermocouples, as well as all pack bay thermocouples werealso routed in the same manner. The waste shoot was capped at the floor in the cabin area with
an aluminum plate sealed in place, which had a slot to accommodate the instrumentation bundle.
Additional sealant was used to seal the slot around the instrumentation bundle.
FIGURE 12. MODIFIED WASTE SHOOT USED AS A CONDUIT AT THE AFT PACK
BAY AREA BULKHEAD
Figure 13 illustrates the cabin layout and equipment proximity as well as basic signal routing for
the flight test setup.
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Aircraft Cabin
FAS
Air
OBOAS
E x i s t i n g
P o w e r
R a c k
Window Plug
DAS
OBIGGS
Air
Air
Air
OBOAS
Compressed Air Bank
(Cargo Bay)
Penetration STA 1275
(CWT Thermocouples)
Penetration STA 1235
(Pack Bay Instrumentation)
Penetration STA 985
(Wing Tank Instrumentation)
Power Cable
System Wiring
Sample Tubing
Purge Air Line
Instrumentation
Wiring
To Avionics Bay
STA 990 STA 1010 STA 1080 STA 1120 STA 1250
FASAnalyzer
Sample System
Penetration STA 1244(CWT Sample Lines)
Wing Tank/Heated
Line Thermocouples
FIGURE 13. DIAGRAM OF INSTRUMENTATION INSTALLATION IN THE
NASA 747 SCA CABIN
2.2 TEST PROCEDURES.
Nine flight tests were performed for a total of 29 hours. An additional 11 hours of ground testing
was performed prior to and during the execution of the flight tests. All tests were performed
from Ellington Field, TX, the center of NASA aircraft operations, with the exception of test 0,which departed from NASA Dryden, Edwards, CA. The ground operation between tests 4 and 5occurred at Davis-Mothem Airbase in Tucson, AZ. The tests were performed during two
different 2-week periods approximately 4 months apart. The primary focus of the testing was to
study commercial transport fuel tank inerting using the FAA-simplified inerting system. Boththe dual-flow and variable-flow operation was studied, with and without fuel in the CWT.
Ullage flammability was measured under a variety of flight and ground conditions in both the
CWT as well as in the wing tank. Additionally, flammability was measured during tests withoutinerting and with a conventional CWT vent configuration. Table 2 gives a list of flight tests
performed on the NASA 747 SCA during the fuel tank inerting and flammability study.
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TABLE 2. TABLE OF INERTING FLIGHT TESTS ON THE NASA 747 SCA
No.
FAA
Designator Date
Flight
Hours Description
1 Pretest 1 12/09/03 2.1 Preliminary OBIGGS proof of concept. CWT approx.
11% [O2], run system gate to gate, ascend to FL 350,cruise until CWT [O2] stable, descend per ATC. CWT no
cross venting.
2 Pretest 8 12/10/03 2.9 OBIGGS performance evaluation. Stabilized system
inputs at three altitudes for three different flows and twodifferent temperatures. CWT no cross venting.
3 Test 0 5/13/04 3.8 FAS Evaluation. CWT not inert, OBIGGS off, operate
FAS gate to gate. Operate ACMs on ground to generateflammability. CWT no cross venting.
4 Test 1 5/19/04 2.1 OBIGGS Demonstration–Dual Flow Mode. CWT
approximate 10% [O2], run system gate to gate, ascend toFL 350, cruise until CWT [O2] stable, descend per ATC.CWT no cross venting.
5 Test 2 5/21/04 2.1 OBIGGS Variation 1–Variable Flow (small orifice).
CWT approx. 10% [O2], run system gate to gate, ascendto FL 350, Cruise until CWT [O2] stable, descend same as
test 1 within limits of ATC. CWT no cross venting.
6 Test 3 5/22/04 2.1 OBIGGS Variation 2–Maximum Flow (wide orifice).CWT approximate 10% [O2], run system gate to gate,
ascend to FL 350, cruise until CWT [O2] stable, descend
same as Test 1 within limits of ATC. CWT no cross
venting.
7 Test 4 5/20/04 4.2 Flammability Reduction Demonstration Part 1–OBIGGSVariable Flow. CWT approximate 10% [O2], 25% fuel
load, run system gate to gate, ascend to max altitude,
cruise until CWT fuel burned and [O2] stable, descend perATC, 3-hour turn-around running ACMs, CWT no cross
venting.
8 Test 5 5/20/04 3.6 Flammability Reduction Demonstration Part 2–OBIGGSVariable Flow. CWT approximate 10% [O2], 25% fuel
load, run system gate to gate, ascend to max altitude,
cruise until CWT fuel burned and [O2] stable, descend perATC, 3-hour turn-around running ACMs, CWT no crossventing.
9 Test 6 5/26/04 6.1 FAS Evaluation. CWT not inert, OBIGGS off, operate
FAS gate to gate, operate ACMs on ground to generateflammability. CWT venting original configuration.
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3. ONBOARD INERT GAS GENERATION SYSTEM.
The FAA prototype OBIGGS was designed to incorporate a dual-flow concept, developed by the
FAA, that provides a low, relatively pure inert gas flow to the tank during taxi, takeoff, and
cruise to obtain a low oxygen concentration. During descent, the system was switched to low-flow mode, which provides a low amount of less pure NEA to the tank to reduce the amount of
air entering the tank through the vent system. The system was modified to allow for a
variable/high flow during the system operation. This allowed the operator on some tests toincrease the amount of flow at higher altitudes to decrease the total amount of air entering the
ullage through the fuel tank vent system during descent.
The FAA OBIGGS consists of a single unregulated flow path that is plumbed to a manifold of
three ASMs. The nitrogen-rich gas that passes through the modules is then plumbed to the CWT
to reduce the oxygen concentration. The flow path has a heat exchanger that controls the ASMinlet temperature and a filter. The flow passes through the ASMs and through the flow control
valves, which allows the system to flow in both low- and variable/high-flow modes. Figure 14
shows a block diagram of the primary components of the OBIGGS. The system is mounted on a
relatively simple aluminum frame in a palletized manner for simplicity of assembly andinstallation.
Heat
Exchanger
Cool Air Source
E x i s t i n g A i r c r a f t B l e e d a i r S u p p l y
Filter
Heater
Shut-Off
Valve
Variable Flow
Valve
F u e l
T a nk
Throttling
Valve A S
M
System Controller
Temperature
Sensor
A S
M
A S
M
A i r c r a f t
P o w e r
Oxygen Rich
Waste Gas
Waste Stream
Discarded
Nitrogen Rich
Product Gas
Low Flow
Orifice
FIGURE 14. SYSTEM BLOCK DIAGRAM
3.1 SYSTEM FLOW.
The inerting system gets its bleed air from a modified main bleed air duct on the aft bulkhead ofthe 747 pack bay at STA 1245, which is reduced to a 2-inch-diameter tube for connection to the
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system shutoff valve (SOV). When energized, the 18-32 Vdc SOV valve opens, allowing flow
into the system, through the heat exchanger bypass Y, into the air/air heat exchanger. The heat
exchanger accepts the 400°F bleed air and uses a 4-inch-diameter cooling bypass loop to cool the
system flow to a temperature of 180°F ±10°. The cooling bypass uses a three-phase, 115 Vac,400-Hz fan to draw outside ambient air through the heat exchanger and uses a 4-inch-diameter,
18-32 Vdc motor-operated, modulating valve to control the airflow through the heat exchanger.This modulating valve is operated by the system temperature controller, but is controlled
manually with a switch box (referred to as the Parker box) by the system operator. The heat
exchanger bypass Y allows a 1-inch-diameter line to bypass a portion of the system flow into the
heat exchanger to decrease the effectiveness of the cooling loop, giving better control of the airtemperature into the ASMs.
After the heat exchanger, the bleed air passes through a desiccating filter, past the temperaturesensor used by the system operator to control the temperature, and through a section of pipe with
a 187-watt clamp heater before entering the ASMs via a manifold. The clamp heater is designed
to increase the temperature of the ASM inlet air significantly if the temperature should drop (due
to system heat rejection) well below the target temperature obtained by the heat exchanger.However, it provided very little additional temperature when the air was maintained close to the
specified temperature.
Once the 180°F cooled bleed air passes into the ASMs, the air is separated into the NEA and
OEA constituents. The NEA portion passes through to the ASM outlet, while the OEA portion passes out the permeate (waste) port. The ASM waste flow is eliminated from the system
through the OEA manifold plumbed into the heat exchanger exhaust box on the bottom side of
the aircraft.
After the OEA is separated, the NEA passes through the flow control portion of the system,
which allows the system to flow at either low-flow (low-oxygen concentration), or variable/high(higher-oxygen concentration) flow conditions. The variable-flow valve can be closed forcing
all the flow through the low-flow orifice, or it can be opened to one of five distinct open
conditions, of different backpressure, allowing the system to give a total of six different flowconditions. As the variable-flow valve is opened, the system backpressure will decrease,
creating progressively more NEA flow, with the NEA oxygen concentration increasing (less pure) as flow increases. Two separate variable-flow valves were used; both were 1-inch, motor-
operated, ball-type SOVs. One had a standard ball with a 1-inch-diameter hole, the other had a
square slot with an effective 0.391-inch-diameter hole.
The NEA can be directed by means of counter-actuated SOVs to either “inert” the CWT or to
“divert” the NEA overboard. When divert is selected, the NEA flows directly to the heatexchanger exhaust box where it mixes back with the OEA and is safely dumped overboard. Ifinert is selected, the NEA flows through a flow meter, a check valve, and finally to the NEA
deposit line.
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3.2 SYSTEM INTERFACES.
The primary inerting system physical interfaces are the attachment brackets that mount the
system to the aircraft. The mechanical interfaces allow bleed air to interface with the system,
NEA to be deposited into the CWT, OEA to be eliminated, and heat exchanger air to be used.Additionally, system electrical connections also provide an interface between the system and the
aircraft power as well as between the system and the operator. The system diagram given as
appendix E identifies each system interface.
3.2.1 System Mounting.
To allow a relatively simple interface with the aircraft, the system pallet was installed in the
number 4 pack bay of the NASA 747 SCA, frequently referred to as the empty pack bay, using
six attachment brackets. The brackets attached the aluminum angle pallet to the fairing supportstructure in the aft right-hand side of the pack bay area. The brackets were made of stainless
steel and were attached using doublers with 1/4″ Steel A/N standard bolts. Figure 15 shows athree-dimensional rendering of the system mounted in the empty pack bay of a 747 with the main
bleed air duct illustrated in blue as a spatial reference.
FIGURE 15. THREE-DIMENSIONAL RENDERING OF THE OBIGGSINSTALLED IN THE PACK BAY
3.2.2 Mechanical Interface.
The primary mechanical interfaces for system operation were the bleed air inlet, the NEAdeposit, the OEA discharge, and the heat exchanger cooling air inlet and exit. Bleed air was
supplied to the system by modifying the bleed air duct (Boeing part no. 69B41284-12) at STA
1245. The modification consisted of welding a 2-inch, commercially pure titanium BMS7-21
grade 3 tee into the main bleed air duct, and using a sealed sleeve assembly to connect the bleedair duct to the OBIGGS SOV assembly. The system SOV was a 2-inch-diameter, 28-32 Vdc
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solenoid operated, mechanically closed valve, Parker part number 5940016 that had a 55-psig
overpressure protection circuit. The overpressure protection feature closes the valve if the static pressure on the system exceeds 55 psi, protecting the system components in the event of a bleed
air system over-pressurization.
The OBIGGS NEA output was a 1-inch Hydroflow™ 14J02 sleeve and coupling connection.The NEA inert/divert tubing assembly, described in section 3.1, was a series of 1-inch
Hydroflow™ fittings with associated 1-inch SOVs adapted to a 16D A/N fitting for mating with
the NEA deposit (see appendix F). The NEA was carried to the CWT through a 1-inch flexibleAE701 wire-reinforced hose with stainless steel over braid lines using MIL-F-83798 specified
816-16D standard fitting ends. The 1-inch flexible line attached to an AN837-16D bulkhead
fitting on the outboard, aft pack bay-canted bulkhead, which passes the NEA into the wheel wellarea. A second flexible line passed the NEA from the A/N bulkhead fitting to the rear spar purge
panel. The NEA entered the CWT through a 1-inch-diameter SwageLok ®
bulkhead fitting on the
rear spar purge panel (see figure 3). Adaptors were used to adapt the A/N fittings to theSwageLok bulkhead fitting. A third 1-inch flexible line was used to carry NEA to a nozzle
mounted on a bracket at the top of bay 6 (right aft most bay) in the CWT. This nozzle consistedof a 90º elbow 16D A/N bulkhead fitting directing the NEA down, and a check valve was placed
immediately before the nozzle to reduce the possibility of fuel seeping back into the inertingsystem. Appendix G contains an installation drawing of the NEA nozzle.
The OEA discharge was connected to the inboard side of the heat exchanger exhaust box via a 2-inch inner diameter (ID) aluminum tube and flexible coupling. A 2-inch check valve was also
used to keep contaminants from entering the ASMs when not in operation.
The heat exchanger cooling air was interfaced with the pack bay exterior through two scoops on
two separate fairing panels that were modified for the flight tests. The heat exchanger inlet doorwas located on fairing panel 192KR, between STA 1169 and 1181, and was approximately 10.5
inches above the bottom edge of the panel. The air inlet door had a semi-circular cross section or
approximately 6 inches in diameter and was mounted in a 13.5- by 12- by 7-inch assembly. Itwas connected to a 4-inch motor-operated air inlet modulating valve using two flexible couplings
and an aluminum tube, which had a 2-inch opening into the air inlet box. The heat exchanger
cooling air exhaust door had a rectangular cross section approximately 6 inches by 3 inches and
was located on access door 192NR, between STA 1223 and 1233, approximately 10.5-inchesfrom the seam of panel 192KR. The cooling air exhaust door was mounted in an assembly 10.5
by 8 by 16 inches and was connected to the heat exchanger by a 4-inch flexible coupling that
attached to an aluminum box fitted to the back of the exhaust door assembly. The NEA bypassline was connected with a 1-inch ID stainless steel flexible hose to a 16D AN fitting on this box.
Figure 16 shows the OBIGGS installed in the empty pack bay of the NASA 747 SCA testaircraft without the two panels described above.
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FIGURE 16. ONBOARD INERT GAS GENERATION SYSTEM INSTALLED IN
TEST AIRCRAFT PACK BAY3.2.3 Electrical Interface.
Each system part had a specified electrical connector to communicate power and signals to the
individual component. They were wired with aviation-grade wiring to a system connector,
allowing the system to easily interface to the OBIGGS control box. The control box allowed thesystem and its components to be turned on or off and to switch the system from one flow mode
to the other (see figure 17). It also provided the system operator with the ASM inlet temperature
and a manual temperature control box. A complete wiring diagram of the system and control
box is shown in appendix H.
FIGURE 17. FRONT PANEL OF OBIGGS CONTROL BOX
3.3 SYSTEM OPERATION.
The system is designed to operate during normal aircraft flight and ground operations, provided bleed air is available. The system low-flow and high-flow conditions were established by setting
two different needle valves during ground operations. The needle valves provide the
backpressure needed to give the necessary system variable performance throughout the flight profile. The aircraft’s auxiliary power unit was used to power the bleed air system to
approximately 30 psi, and the low-flow mode needle valve was adjusted to generate NEA with 5
percent oxygen at sea level conditions. The ASM inlet temperature was allowed to stabilize at
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23
180°F before setting the needle valve with the variable/high-flow valve closed. For the first test,the high-flow mode needle valve was set to generate NEA with 11 percent oxygen at sea level.
After the first test, the variable-flow valve was installed, and the high-flow needle valve was
removed. Instead of a fixed needle valve configuration, the NEA conditions (flow/purity) werechanged by opening and closing the valve in increments. The low-flow mode was primarily used
for taxi, takeoff, climb, and cruise phases of flight, while the variable/high-flow mode was used primarily for the descent phase of flight and during the ground-taxi back to the gate.
It is considered essential that the OBIGGS be maintained at 180°F ±10° for efficient
performance. The system operator controls the ASM inlet temperature manually using thesystem temperature controller. The operator adjusts several potentiometers that control the
position of the 4-inch-diameter cooling air modulating valve for the heat exchanger. This
modulating valve needed to be continually adjusted due to constantly changing conditions(altitude, bleed air pressure, pack bay temperature) on the aircraft during a typical flight. The
operator used the temperature readout display on the OBIGGS control box to monitor cooling
system performance. The readout display received its signal from a T-type thermocouple that
was installed just before the ASM inlet manifold.
The operator could use the heat exchanger bypass valve if necessary to bypass a small amount offlow (10%-20%) around the heat exchanger to decrease the affectivity of the heat exchanger.
This made controlling the temperature on the ASMs easier under some conditions.
During system warmup, maintenance, and testing, there was a need not to effect or disrupt theCWT environment, so a NEA divert valve was used to direct the NEA product away from the
CWT. The inert/divert switch was located on the OBIGGS control panel and operates two
opposing 1-inch-diameter, 28-32 Vdc motor-operated SOVs (see appendix F). When divert wasselected, the inert SOV closes, and the divert SOV opens and deposits the NEA overboard.
When inert was selected, the divert SOV closes, and the inert SOV opens, allowing the NEA totravel to the CWT.
The system required the operator to change from low to variable/high-flow mode manually.Low-flow mode gave the most pure (lowest oxygen concentration) NEA the system could
generate with the fixed low-flow orifice and the given aircraft conditions. Variable/high-flow
mode was adjusted by incrementing an “Increase/Decrease” switch on the OBIGGS control panel. The increase/decrease switch controlled a 1-inch-diameter, 28-32 Vdc motor-operated
SOV. The variable/high-flow mode can allow the system to produce higher volumes of NEA of
greater oxygen concentrations (less pure) at higher altitudes. This system feature allows greater
flow into the tank during aircraft descent to minimize air entry into the ullage due to increasing
static air pressure. This creates lower resulting ullage oxygen concentration than if the low-flowmode was simply employed the entire flight cycle.
4. ANALYSIS.
Data analysis was performed in two different categories: inerting calculations and flammability
calculations.
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4.1 INERTING CALCULATIONS.
The primary calculations performed to analyze the inerting test data were to determine the
quantity of bleed air consumed by the system and the bulk average oxygen concentration.
Additionally, a simple inerting model was used to calculate the oxygen concentration in a tankvolume, given a flight profile and performance schedule of the OBIGGS.
4.1.1 Bleed Air Consumption.
System bleed air flow was calculated using an equation developed from flow in and out of theASM and a mole balance of oxygen in and out of the ASM. The combination of these equations
gives the following equation for bleed air flow in terms of NEA flow.
)][O(0.21
)][O]([O
2
22
Perm
Perm NEA NEA Bleed QQ
−
−⋅= && (1)
With: = NEA Oxygen Concentration NEA][O2
Perm][O2 = OEA Oxygen Concentration
A more complete derivation of the equation is given in reference 5.
4.1.2 Average Fuel Tank Oxygen Concentration.
To allow for a fair comparison between different flight tests, it is critical to express the oxygen
concentration of the tank as a whole, even though the concentrations of the individual bays oftenvary. To achieve this, a weighted average by volume was calculated, given the oxygen
concentration distribution at a given time. This average weighed the oxygen concentration ofeach bay with the total tank volume percentage of each bay.
(2)]60.13[O]50.13[O]40.10[O]30.10[O]20.23[O]1[O31][O
222
2222
Bay Bay Bay Bay Bay Bay. Average
+++
++=
4.1.3 Inerting Model.
A simple analytical model was developed to calculate the average tank ullage oxygen
concentration, given a specific tank volume and system performance schedule, to compare to the
measured tank average oxygen concentration data. The model calculates the mass of oxygen in
the tank at the start of the mission, given a starting tank oxygen concentration, and tracks themass of oxygen in and out of the tank, given the changing system performance and flight
conditions including the appropriate net oxygen entering the tank as a result of descent. Thefollowing equation governs the model process.
21)()1()()1()1()(22 OO
.*V *t UGOF V *t UGOF m IGOF mt mt m Tank Tank ρ ρ ∆+−∗∆−−∗−∗+−= && (3)
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In this equation, UGOF (t -1) is the fraction of oxygen in the ullage gas. It is calculated by
dividing the mass of oxygen in the tank at t -1 by the mass of gas in the tank ullage or:
(4))1()1()1(2O
−−=− t m / t mt UGOF Tank
Where: = Mass of oxygen in tank at time t )(2O t m
= Mass flow rate of inerting gas (in terms of t )m&
IGOF = Fraction of oxygen in inerting gas∆ρ = Change in ullage density due to altitude changeV Tank = Volume of tank ullage
mTank = Mass of gas in tank
mair = Mass of air entering tank
A more detailed description of the model process is given in reference 5.
4.2 FLAMMABILITY CALCULATIONS.
The primary calculations performed to analyze the flammability test data were simplified fuel airratio (FAR) calculations using an FAA-developed model. Additionally, a more complex ullage
flammability model was employed.
4.2.1 Estimation of the Vapor Generation in the CWT.
The vapor generation model used by the FAA has been developed by Professor C. E.Polymeropoulos of Rutgers University, and is still in its validation phase. The model employs
free convection heat and mass transfer correlations in a fully mixed tank. It requires
experimental data on the liquid fuel temperature, the tank walls, the ambient temperature and
pressure, and generates, numerically over time, the total mass of vapor generated and the vapormasses of the component species used to characterize the liquid fuel. The user is able to input
pressure, liquid fuel, and wall temperatures as functions of time, and can select from thecompositions of several different flashpoint fuels. Part of the model can also calculate the
equilibrium vapor concentrations at different pressures and temperatures. More detailed
information about this model can be found in reference 8.
4.2.2 Fuel Air Ratio Calculator.
The FAR calculator, developed by the FAA’s Chief Scientific and Technical Advisor for fuel
system design, is by comparison a much simpler model, but it still provides a great amount of
useful data. This model predicts fuel vapor pressure, and therefore, FAR for a wide range offuels over a wide range of altitudes, temperatures, and mass loadings. This model, however,
only calculates equilibrium values occurring under isothermal conditions and, therefore, is aconservative estimate of the FAR. The model also offers several other features, such as being
able to enter ASTM D 2887 distillation curve and flashpoint data to generate a customized fuel
for use in the model and predicting such things as the flashpoint of a given fuel, molecular
weight of the vapor, and the temperature needed to arrive at a stoichiometric mixture. The model
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and further associated information can be found online at www.fire.tc.faa.gov/systems/
fueltank/downloads.stm.
5. DISCUSSION OF RESULTS.
The results of the flight tests are presented for two areas of analysis: fuel tank inerting and fuel
tank flammability.
5.1 FUEL TANK INERTING.
The primary focus of the fuel tank inerting data is the changing system performance, given
different flow modes and orifice settings. Additionally, the effect of these flow conditions on
OBIGGS bleed air consumption was examined. Also, the ability of the system to inert the given
aircraft CWT was examined for both the average fuel tank oxygen concentration and thedistribution of oxygen within the compartmentalized tank.
5.1.1 Inerting System Performance.
The primary factors affecting the inerting system flow and purity are the pressure on the systemand the altitude (pressure) at the OEA vent. Figure 18 illustrates these two parameters for the
OBIGGS NEA flow and purity for a test using the basic dual-flow methodology. As expected,
increases in pressure on the ASM resulted in greater NEA flow and a lower NEA oxygen
concentration (more pure), given a fixed orifice. The NEA oxygen concentration will decreasewith increased flow when the NEA deposit orifice is fixed. This is due to the fact that an
increase in flow across a fixed orifice will result in a greater pressure drop and an increase in
pressure drop across this system flow orifice will result in a decrease in oxygen concentration.
0
5
10
15
20
25
0 20 40 60 80 100 120 140 160
Time (mins)
O x
y g e n C o n c e n t r a t i o n ( % v o l )
0
10
20
30
40
50
60
70
A l t ( 1 0 0 0 f t ) \ P r e s s u r e ( p s i a ) \ F l o w ( s c f m )
NEA [O2] NEA Flow ASM Pressure Altitude
Test 1 Data - OBIGGS Performance
FIGURE 18. SYSTEM PERFORMANCE DATA FOR A TYPICAL FLIGHT TEST
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Figure 19 illustrates the ASM pressure for the taxi/takeoff portion of three different tests with
three different ascent rates. This graph illustrates the very similar pressure profiles the systemwas exposed to at the inception of each test, particularly the period just after takeoff for
approximately 4 minutes. Figures 20 and 21 illustrate the NEA purity and flow, respectively, for
the same three tests during the same time period. Each test had an adjusted time to allow for
comparison of the parameters. Figures 20 and 21 illustrate the somewhat wider range of performance for this same time period.
0
10
20
30
40
50
60
70
15 20 25 30 35 40 45
Adjusted Time (mins)
P r e s s u r e
( p s i a )
0
5
10
15
20
25
30
35
40
A l t i t u d e ( 1 0 0 0 f t )
Test 1 ASM Pressure
Test 2 ASM Pressure
Test 4 ASM Pressure
Test 1 Altitude
Test 2 Altitude
Test 4 Altitude
ASM Pressure Comparison
FIGURE 19. COMPARISON OF ASM PRESSURE DURING THE INCEPTION OF THREE
DIFFERENT FLIGHT TESTS WITH ALTITUDE
Further examination of the system input conditions illustrates that the system input temperature
was consistent for each test, but each had a significantly different output temperature, indicating
a different level of heat soaking in the ASMs. For each test, the system was run prior to the test,
but for different periods of time, each test having the system off prior to taxi (system on for test)for a different amount time. Also, the ACMs were run in different ways prior to each test,
creating different temperature conditions in the pack bay area where the system was housed. All
these factors had an effect on how heat soaked (steady temperature operation) the ASMs are,
which created these unique performance conditions for the initial part of each system operation.This is evident in figure 22, which illustrates a similar ASM temperature input range for each of
the tests during this time period (21 to 25 minutes) but very different NEA temperatures (ASMoutput). ASM temperature changes the permeability characteristics of the ASM, which causes
these marked changes in system performance observed in figures 20 and 21. Presumably, these
variations would be greater if the ambient temperatures were colder. Ambient temperaturesranged from 80º to 95ºF with varying amounts of sun and wind for these three tests.
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0
2
4
6
8
10
12
14
16
18
20
15 20 25 30 35 40 45
Adjusted Time (mins)
O x y g e n C o n c e n t r a t i o n ( v o l % )
0
5
10
15
20
25
30
35
40
A l t i t u d e ( 1 0 0 0 f t )
Test 1 NEA [O2]
Test 2 NEA [O2]
Test 4 NEA [O2]
Test 1 Altitude
Test 2 Altitude
Test 4 Altitude
NEA [O2] Comparison
FIGURE 20. COMPARISON OF NEA PURITY DURING THE INCEPTION OF THREE
DIFFERENT FLIGHT TESTS WITH ALTITUDE
0
5
10
15
20
25
30
35
40
15 20 25 30 35 40 45
Adjusted Time (mins)
F l o w ( s c f m )
0
5
10
15
20
25
30
35
40
A l t i t u d e ( 1 0 0 0 f t )
Test 1 NEA Flow
Test 2 NEA Flow
Test 4 NEA Flow
Test 1 Altitude
Test 2 Altitude
Test 4 Altitude
NEA Flow Comparison
FIGURE 21. COMPARISON OF NEA FLOW DURING THE INCEPTION OF THREE
DIFFERENT FLIGHT TESTS WITH ALTITUDE
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Figure 23 illustrates the ASM inlet pressure for the descent/landing portion of three differenttests with three similar descent profiles. Each test used a different valve and methodology for